Interhemispheric integration in the neural face perception network : Does stimulus location matter?
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MIT Press
Abstract
The neural mechanisms underlying hemispheric lateralization can be investigated using neuroimaging methods and
modelling techniques. In some experiments, sensory information is initially presented exclusively to one hemisphere,
for example, by displaying a visual stimulus in the periphery of the contralateral hemifield. This experimental design
enables, among other things, a comparison of competing theories of interhemispheric integration (e.g., interhemispheric
inhibition vs. interhemispheric recruitment). However, the underlying neural models for peripheral stimulation
may differ from those for central stimulation and, therefore, may not adequately describe the mechanisms associated
with typical, foveal stimulus processing. To address this question, the present functional magnetic resonance imaging
(fMRI) study analysed the influence of stimulus location (peripheral vs. central) on neural network connectivity, particularly
interhemispheric transfer, as determined by dynamic causal modelling (DCM), for a face perception task. Face
and object images were presented either peripherally or centrally to a group of healthy volunteers (N = 17). By contrasting
brain activations for faces against objects, we identified bilateral face-sensitive
regions, such as the left and
right fusiform face area (FFA) and the occipital face area (OFA). Additionally, we extracted the bilateral primary visual
cortex (V1) as the input region for our neural models. We constructed five increasingly complex models that differed
only in their modulatory connectivity. Bayesian model averaging (BMA) was employed to average the parameters
across all models, enabling the calculation of interhemispheric transfer difference (i.e., left-to-
right
minus right-to-
left
modulatory connectivity parameter) and the strength of interhemispheric transfer between bilateral OFA and FFA
regions. Our findings demonstrate that interhemispheric integration depends on stimulus location. Peripheral presentations
of faces induce different connectivity patterns compared with centrally depicted faces. Specifically, we
observed larger interhemispheric transfer differences for peripheral face stimuli compared with central stimuli. In
conclusion, peripheral and central presentations of faces modulate the face processing network differently, with left
and right visual field presentations yielding asymmetrical connectivity patterns. Since faces are preferentially processed
via the fovea, the typical face processing network likely aligns more closely with activation patterns elicited by
central stimuli. In contrast, connectivity patterns triggered by peripheral stimulation may represent an atypical processing
style and cannot be directly compared with those activated by central stimuli.
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Except where otherwised noted, this item's license is described as Attribution 4.0 International